Soya-Based Coatings and Adhesives - ACS Symposium Series (ACS

Dec 23, 2014 - Soy-Based Chemicals and Materials. Chapter 10, pp 207–254. DOI: 10.1021/bk-2014-1178.ch010. ACS Symposium Series , Vol. 1178...
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Chapter 10

Soya-Based Coatings and Adhesives

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Xiaofeng Ren and Mark Soucek* Department of Polymer Engineering, The University of Akron, Akron, Ohio 44325 *E-mail: [email protected]

Utilization of the soybean as a renewable source to produce biodegradable coatings and adhesives will reduce dependence on petroleum feedstock and add value to agricultural by-products. The United States is a leading producer of soybeans around the globe, growing roughly 80 million metric tons of soybeans a year. Soybean oil and soybean protein are two major products of soybean seeds. The traditional soybean market as food and animal feed has been saturated. New non-food industrial applications are desired to be developed for consuming the oversupplied soybean. In this chapter, a review is made in terms of the soya-based coatings and adhesives derived from renewable soybean resources. The development of soya-based alkyd coating, epoxy coating, urethane coating, UV-curable thiol-ene coating, as well as hybrid coating are elaborated. Soy protein-based adhesives for wood composites, and soybean oil-based pressure sensitive adhesives are also discussed.

1. Soya-Based Coatings Polymeric coatings based on petrochemicals have wide applications in modern industrial society. However, petrochemicals are not renewable, and most petrochemical-based coatings contain significant amounts of volatile organic compounds (VOCs), which are environmental pollutants (1–6). The coatings industry is currently challenged by stricter environmental regulations enforced by government agencies. The fast-depleting petroleum reserves and the environmental concerns from petrochemicals are pushing the industrial utilization of renewable resources. Vegetable oils, i.e., soybean oil, have been used since 19th © 2014 American Chemical Society In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

century as chemicals in the coating and paint industry (7, 8). Soybean oil has the advantage of being low-cost, readily available, and renewable with high annual production in the USA. During the last decade, a variety of soybean oil-based coating systems have been developed (9–11).

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1.1. Soybean Oils Soybean oils are extracted from the seeds of soybean mostly for human consumption (2, 3). The unsaturated C=C in soybean oils polymerize via autoxidation as thin films in the presence of atmospheric oxygen (12, 13). The chemical composition of soybean oils arises from the esterification of glycerol with three fatty acid molecules, as shown in Figure 1. Soybean oil is made up of a mixture of triglycerides bearing different fatty acid residues. The typical fatty acid composition in soybean oils is given in Table 1. The most important parameters affecting the physical and chemical properties of oils are the stereochemistry of the double bonds of the fatty acid chains, their degree of unsaturation, as well as the length of the carbon chain of the fatty acids (13, 14). The average degree of unsaturation is measured by the iodine value, which corresponds to the amount of iodine (g) which reacts with the double bonds in 100 g of the oil under investigation. Vegetable oils are divided into three groups depending on their iodine values. The oils are classified as “drying” if their iodine value is above 140, “semi-drying” if this parameter ranges from 125 to 140, and “non-drying” when it’s below 125. Soybean oil has an iodine value around 130, and thus is a semi-drying oil (15).

Figure 1. General triglyceride structure and fatty acids commonly found in soybean oils (13, 14). 208 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Table 1. Typical fatty acid composition of soybean oils (13). SOURCE: Reproduced with permission from reference (13). Copyright 2010 Royal Society of Chemistry.

1.2. Autoxidation of Soybean Oils Soybean oils can undergo autoxidation with the help of an oxygen atmosphere to form crosslinking networks (Figure 2). The process of autoxidative curing of soybean oil with initiation, propagation and termination steps is shown in Figure 2. In the initiation step, naturally occurring hydroperoxides decompose to form free radicals. These free radicals react with the fatty acid chains of the drying oil. The propagation then proceeds by the abstraction of the hydrogen atoms present between double bonds of the methylene groups, which lead to the free radical (a). Radical (a) is resonance stabilized and can react with oxygen to form radical (b) shown in Figure 2. Crosslinking proceeds until the termination step which results in the formation of structures C-C, C-O-C and C-O-O-C. Cobalt, lead and zirconium-2-ethylhexanoates are generally used as catalysts for oxidative polymerization of soybean oil (8, 13).

1.3. Soybean Oil-Based Coatings Because of the low reactivity of the double bonds within the soybean oils molecule and the flexibility of the triglyceride fatty acid structure, soybean oils are usually chemically modified to be useful for applications in industrial products. Various chemical pathways for functionalization of these triglycerides have been studied. A lot of efforts have been made to chemically modify soybean oils in order to enhance their reactivity and improve the final coating properties over the last few decades. Soybean oils with acrylate groups have been synthesized via epoxidation and then acrylation of the double bonds in fatty acid chains, which can rapidly polymerize via a radical mechanism to afford thermoset coatings with good thermal and mechanical properties (1, 8, 16). Hydroxyl groups have also been introduced into soybean oils by different methods to generate polyols, which could react with isocyanates to produce polyurethanes with properties comparable with petrochemical-based polyurethanes (17). 209 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Figure 2. The autoxidation of soybean oils (8). (Adapted with permission from reference (8). Copyright 2006 Elsevier.).

1.3.1. Coatings from Copolymerization of Soybean Oil with Vinyl Monomers One of the oldest methods for the modification of soybean oils is the copolymerization of oils with vinyl monomers like styrene, divinylbenzene, and cyclopentadiene (8, 18). The products have improved film properties, and can be used in the formulation of surface-coating materials. The polymerization of styrene modified-soybean oils involves free radical initiated polymerization. Generally, peroxide free radical initiators are used to accelerate the copolymerization reaction (19). Styrene-oil copolymerization has been extensively investigated by Larock et al (18–20). Cationic copolymerization of soybean oil with styrene and divinylbenzene leads to various copolymers (Figure 3). Cationic polymerization of the soybean oil with divinylbenzene comonomer initiated by boron trifluoride diethyl etherate results in polymers ranging from soft rubbers to hard thermosets, depending on the oil and the 210 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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stoichiometry employed. The copolymerization of soybean oil with styrene and dicyclopentadiene initiated by boron trifluoride diethyl etherate resulted in polymers with good mechanical properties and thermal stability (8). The tensile properties of several soybean oil polymers ranges from elastomers to hard, ductile and relatively brittle polymers (20).

Figure 3. The proposed process of crosslinking of soybean oil with styrene and divinylbenzene (8). (Adapted with permission from reference (8). Copyright 2006 Elsevier.).

Acrylated epoxidized soybean oil (AESO), synthesized from the reaction of acrylic acid with epoxidized soybean oil has been extensively studied in polymers and composites (Figure 4) (8, 9, 21, 22). AESO could be mixed with styrene as a reactive diluents to improve its processability and afford AESO-Styrene thermosets and composites appropriate for structural applications (9). The properties of the resulting polymer can be tailored either by changing the acrylate level of the triglyceride, or by varying the amount of styrene. It was found that the elastic modulus E′ and glass transition temperature Tg of the resulting coatings increased with increasing styrene content in the copolymers. As a result, a wide ranges of properties and applications have been obtained by tailoring the styrene amounts, making these biopolymers suitable replacements for petroleum-based polymers (9). To make the nonconjugated soybean oils undergo free radical polymerization more easily, conjugated soybean oils have been prepared using a rhodium-based catalysts developed by Larock et al (23). These conjugated soybean oils subsequently underwent copolymerization with styrene, acrylonitrile, and dicyclopentadiene (24–26). The copolymers obtained incorporated up to 96 wt% of the conjugated oils, and a wide range of thermal and mechanical properties were obtained by simply changing the stoichiometry of the soybean oils and the petroleum-based monomers (13). 211 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Figure 4. Synthesis of AESO

As a reactive diluent for soya-based polymer systems, styrene works well and is relatively low cost. However, styrene is a VOC and hazardous air pollutant (HAP). The US Department of Health and Human Services added eight substances including styrene to its Report on Carcinogens (ROC), a science-based document that identifies chemicals and biological agents that may put people at increased risk for cancer on June 14, 2011. The National Toxicological Program’s (NTP) 12th Report on Carcinogens classifies styrene as “reasonably anticipated to be a human carcinogen” (27). Therefore, the market of styrene as a reactive diluent is shrinking.

1.3.2. Soya-Based Alkyds Coatings Alkyd coatings are derived from the reaction of a polyol, a polyvalent acid or acid anhydride, and fatty acid derivatives. Alkyds might be one of the oldest applications of vegetable oil renewable resources in polymer science (28). 212 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Alkyds prepared from soybean oils, glycerol, and polybasic acids have a long history for coating application. However, full-scale commercial production of alkyd resins began in 1933 at General Electric. Once commercialization started, the alkyd resins enjoyed rocketing growth and replaced the raw soybean oils as binders, since they offered much better coating properties than the raw oil did at a fairly low price (29–34). However, the introduction and development of synthetic polymer and resins for the coating industry considerably damaged the position of the alkyd resins (31, 34). The synthetic polymer based coating such as acrylate dispersions, urethanes, melamine-polyesters, PVCs, etc. took up a huge share of the market due to features such as shorter drying times, improved long term exterior durability, and lower price compared to the traditional alkyds. A resurgence in alkyd technology took place recently in coatings due to restrictions on VOCs and the push for environmentally friendly coatings. Alkyd resins in the form of alkyd emulsions, alkyd based hybrids and high solids alkyds offer very attractive solutions to the environmental problems the coating industry is facing with. It has been shown that alkyd emulsions could reduce the VOCs in the coating formulation to a level which is incomparably low compared to other environmentally friendly coating systems. When properly formulated, alkyd emulsions can be considered as candidates to formulate coatings with a zero VOC level (34–36).

1.3.2.1. Advantages of Alkyds Renewability. A large portion of starting materials for alkyds synthesis, except for phthalic anhydride (PA) as an acid anhydride being petrochemical origin, is based on readily available and renewable fatty acids and glycerol from vegetable oils or other natural sources. This makes alkyds very interesting coating components from an ecological point of view (31–36). Glycerol is usually used as the polyol for alkyd synthesis. As a by-product of biodiesel production, glycerol is an important starting material when considering the sustainability of soy materials derived chemicals. The production of fatty acids and esters (biodiesel) from triglycerides gives about 10 wt% of glycerol and is becoming increasingly abundant (29, 30). Therefore, glycerol is currently discussed as a platform chemical of a future biobased chemical industry. Alkyd is one of those important industry. There is no doubt that alkyd resins have attracted the interests of many chemists, especially from the academia, as could be seen from the huge number of publications covering this field. Low cost. The vegetable oils, glycerol, and PA, as starting materials for alkyd synthesis are cost-effective materials. The increased price on fossil oil has affected the raw material prices for fossil based resins more compared to renewable resources such as vegetable oils. The prices of vegetable oils and glycerol are relative stable compared to those of the fossil oil. Alkyds are very versatile polymers due to their compatibility with many polymers such as nitrocellulose, phenolic resins, epoxy resins, amino resins, silicone resins, chlorinated rubber, cyclized rubber, hydrocarbon resins, and 213 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

acrylic resins. This versatility, along with the extremely wide formulating latitude, made alkyds suitable for the production of a very broad range of coating materials. These factors together have during the last decade triggered extensive research and development on traditional alkyds as well as on development of new type of coating systems emerging from the alkyds.

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1.3.2.2. Synthesis of Alkyds There are two primary methods for alkyd preparation: monoglyceride process and fatty acid process. In the monoglyceride process (Figure 5), vegetable oil is used and reacted with polyol, typically glycerol, to generate a monoglyceride product via a transesterification reaction. In a second step a polybasic acid, such as PA, is added to the monoglyceride to form an alkyd resin via an esterification reaction. In the fatty acid process, fatty acid, polyol and acid are reacted all in one step. The fatty acid process has the advantage of more process control, and the monoglyceride has the advantage of low cost (15).

Figure 5. Synthesis of alkyd via monoglyceride process.

Alkyd resins are classified according to their oil length. Oil length refers to the oil weight percentage of an alkyd. A short oil alkyd contains below 40% of oil. When oil amounts increase between 60% and 40%, it is called medium oil length. Above 60%, the resin is a long alkyd. Oil length is the important factor, which affects the properties of the final product. Short oil alkyds are most used for baked finishes on automobiles, refrigerators, stoves, and washing machines. Long oil alkyds are typically used in brushing enamels (15).

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1.3.2.3. Modification of Soya-Based Alkyds

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Alkyds have the disadvantages including lack of hardness, low hydrolytic stability, poor alkali resistance, poor exterior weatherability and color retention which diminished alkyd usage (37). Thus modifications of alkyds are imperative for the application. Alkyd hybrid coating is one of the most important modification methods. Some of the main issues for current systems based on alkyd technology range from hybrid alkyd/acrylate systems, alkyd emulsions, modified oils, to UVcurable oil based coatings (38–42).

1.3.2.3.1. Acrylic-Alkyd Hybrid Over the last half century, researchers have developed many methods to modify alkyd resins as environmental regulations have tightened. The first modification made to alkyd resins was done with styrene over the last 50 years (15, 43). A styrenated-alkyd structure is shown in Figure 6. Styrene modified alkyds have the advantage of lower cost, faster drying, reduced viscosity systems thus less solvent required. However, the end-use applications for styrene modified alkyds are virtually limited to primers. Moreover, styrene has been recognized as a carcinogen (27). As stricter environmental regulations on coating formulations continue to be enforced, new modification methods for alkyds with low VOC and with precise control over molecular structures are desirable.

Figure 6. Styrene modified alkyd resin.

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Compared to alkyds, waterborne latex technology has the advantages of faster drying, as well as easier and wide application and clean-up (38). A hybrid polymer comprised of an acrylic dispersion and an alkyd emulsion/solution might combine the advantages of both the acrylic and alkyd. Thus, research of waterborne alkyds is gaining popularity. The most common technique for formation of an acrylic-alkyd hybrid based on the literature review is through mini-emulsion polymerization. Several research groups have investigated the development of acrylic–alkyd hybrid systems using a mini-emulsion process. It has been shown that the hydrolytic stability of the acrylic-alkyd emulsion system can be obtained and adjusted by careful selection of monomers used in the acrylic portion of the formula (38). Soucek and coworkers have investigated the acrylic-alkyd system prepared by free radical polymerization. A water-reducible acrylic-alkyd hybrid resin was made from alkyd resins with varying oil lengths. Long, medium, and short oil alkyds were prepared using soybean oil, glycerol, PA, and tetrahydrophthalic anhydride (THPA) as the alkyd phase. Acrylic co-monomer formulas containing methyl methacrylate, butyl acrylate, methacrylic acid, and vinyl trimethoxysilane were polymerized in the presence of the different alkyds. Acrylic monomers were introduced to alkyd resins with different levels of unsaturation in the backbone, different ratios of acrylic to alkyd, and different oil lengths of the alkyd resins under monomer starved reaction conditions (38). It was found that the oil length of the alkyd and acrylic to alkyd ratio are two of the most important factor for final coatings properties of the resins. The researchers concluded that the hydrolytic stability of the resulting acrylic-alkyd was dependent on the acrylic to alkyd ratio. The oil length of the alkyd backbone had a minimal effect on stability of the resin and film performance in terms of pencil hardness, impact resistance, solvent resistance, crosslink density, and dry time. Acrylic to alkyd ratio was found to play an important role in resin characteristics, such as acid number, molecular weight and hydrolytic stability, while having a minimal effect on the measured coating properties. The performance of resulting acrylic-alkyd hybrid was, to a large extent, dependent on oil length of the alkyd phase. The varying addition of THPA did not show significant effect on overall resin performance, which might be due to a lack of reactivity. Thus, the grafting mechanism had more control over the end properties than the other factors (38). To identify the specific graft locations, 1D and 2D NMR spectroscopy techniques were utilized (40, 41). It was found that grafting between the acrylic and alkyd phases was achieved by hydrogen abstraction at methylene positions found on the fatty acid chains (Figure 7), along with side reactions by abstraction of hydrogens along the polyol segment of the polyester backbone. The 2D-gradient heteronuclear multiple quantum coherence (gHMQC) spectra show no evidence of grafting across double bonds on either the fatty acid side chains or the THPA backbone. It was also determined that choice of initiator has no effect on graft location. These discoveries gave explanation to the conclusions made above.

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Controlled free radical polymerization (CFRP) processes have also attracted the attention of polymer chemists for the past decade. Reversible-addition fragmentation chain transfer (RAFT) polymerization is one of the most important CFRP. RAFT polymerization has the advantages of diversity in monomer choices, versatility in fabricating complex materials with controlled molecular weights, controlled block locations, and narrow molecular weight distributions (44). It was shown that the RAFT mediated reaction imparted a more controlled free radical process for the synthesis of acrylic-alkyd materials. Use of the alkyd macro-RAFT agent provided a new path to acrylic-alkyds that imparted a more controlled way to tailor specific material properties (39). Acrylic modified alkyds were achieved from sequential polymerization of acrylic monomers in the presence of alkyd macro-RAFT agents. Macro-RAFT agents were reached by end-capping a soya-based alkyd with a carboxy-functional trithiocarbonate. The resulting material was then utilized as the RAFT chain transfer agent to affix acrylic blocks onto the alkyd backbone. Butyl acrylate, ethyl acrylate, methyl methacrylate, and ethyl methacrylate were the acrylic monomers used to achieve the acrylic blocks both individually and in combination (39). The synthesis of co-acrylic-alkyd block structures is given in Figure 8. By employing a RAFT-mediated mechanism, better control of acrylic location is expected over commercial acrylic–alkyd resins that are achieved by free radical chemistry. For free-radical polymerization process, side reactions are expected including radical-radical termination, reaction at pendant fatty acids, and homo-polymerization. All these side reactions are expected to be limited with the RAFT process. The demonstration of constructing acrylic-alkyd materials using RAFT polymerization techniques has established a novel way to achieve acrylic-alkyd resins with precise control for use in coatings (39).

1.3.2.3.2. Urethane Modified Alkyd Urethane modified alkyds (uralkyds) are oil-modified polyurethane coatings that are generally produced by the reaction between a diisocyanate with a mixture of mono- and di-glycerides obtained from the alcoholysis between oils and polyol (45). The properties of urethane alkyds depend on the type and amount of oil, polyol, and isocyanate used in their preparation. In general, urethane alkyd is prepared by a two-step procedure. In the first step, triglyceride oil is reacted with a polyol until the reaction mixture is completely soluble in alcohol. In the second step, a diisocyanate is added to the reaction mixture and the remaining hydroxyl groups react with isocyanate groups to form the urethane linkages. Glycerol as a polyol, along with soybean oil, is the most widely used components in urethane alkyd preparation (43).

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Figure 7. Grafting mechanism of acrylic-alkyds via hydrogen abstraction and fatty acid methylene and hydrogen abstraction from polyol segment of the alkyd.

Figure 8. Synthesis of co-acrylic-alkyd block structures from acrylic–alkyd RAFT mediated polymers (39). (Adapted with permission from reference (39). Copyright 2012 Elsevier.).

1.3.2.4. Soya-Based Reactive Diluents in Alkyd Resin It’s desirable for the coating industry to produce high-quality organic coatings with low solvent amount. Conventional solvent-borne coatings usually contain 30-60 wt % volatile materials which pose threat to the environment and human health. Requirement for low VOC coatings is one of the main driving force to develop “environment-friendly” or “greener” coating technologies (46). Techniques such as powder coatings, water-borne coatings, UV radiation curable 218 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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coatings, and high solid coatings have been used to reduce VOCs. Several investigations in the past decade have focused on high solid coatings due to their environmental effect, performance, and economic benefits (46–50). However, the development of high solid coatings has the difficulty in achieving an appropriate viscosity for application, as well as the difficulty in achieving a curing rate that is not significantly lower than that of conventional coatings. Those difficulties created several technological challenges (51). It’s widely accepted that decreasing the viscosity of the polymer reduces the amount of organic solvent. Preparation of a low viscosity coating requires the use of polymers having either a low molecular weight or a narrowed molecular weight distribution (46). For this purpose, many investigators suggested new methods for preparation of low viscosity resins. The use of reactive diluents is an effective means of achieving high solid alkyd formulation. A reactive diluent lowers the viscosity of the coating formulation such that the consistency of the formulation is appropriate for the coating process. It serves as a solvent and then participates in the film formation by taking part in the curing process. Low viscosity, low volatility, good compatibility with the binder, and ability to polymerize either by homopolymerization or copolymerization with alkyd under the cure conditions are the key requirements of a good reactive diluent. If the reactive diluent is derived from renewable sources like soybean oils, it would provide additional environmental benefits by reducing the VOC content and provide biodegradable properties to the final film (46, 49, 50, 52).

1.3.2.4.1. Acrylated Conjugated Soybean Oil as Reactive Diluents Low viscosity and the ability to undergo autoxidative curing make vegetable oils an attractive choice for use as reactive diluents (52, 53). Soucek and coworker prepared three tung oil-based reactive diluents by functionalizing tung oil with three different functional groups of acrylate monomers including alkylsiloxane, triallyl ether, and fluorinated alkyl, via a Diels–Alder reaction (53). However, tung oil is expensive, and its films discolor rapidly due to the presence of the three conjugated double bonds (46). These shortcomings were the driving force behind the efforts to synthesize conjugated soybean oils for modification with acrylate monomers. Compared with tung oil, soybean oil remains a dominant renewable feedstock and is a more attractive choice for use as a reactive diluent due to its readily availability and low cost. Conjugated soybean oil was synthesized via rhodium-mediated isomerization (Figure 9). This oil was then modified via a Diels-Alder reaction with different acrylate monomers: methacryloxypropyl trimethoxysilane, 2,2,2-trifluoroethyl methacrylate and triallyl ether acrylate (Figure 10). This is similar to the tung oil modification reported by Wutticharoenwong and Soucek (53). The resulting functionalized soybean oils acted as reactive diluents by reducing the viscosity of the long oil alkyd formulation by up to 86% (52). Triallyl ether functionalized soybean oil (Figure 10.C) resulted in the highest reduction in the viscosity of the alkyd formulations. Alkoxy silane (Figure 10.A) and allyl ether functionalities 219 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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take part in the film formation via condensation and autoxidative curing, respectively. These two reactive diluents improved the tensile strength, tensile modulus, crosslink density and glass transition temperature. While fluorinated alkyl functionality (Figure 10.B) does not take part in film formation, it affects the properties of the final film, including surface energy, thermal stability, hydrophobicity, and solvent resistance (52, 53). The reduction or substitution of VOCs in coatings processing by using reactive diluents derived from renewable and cost-effective materials should be an important advancement in the mitigation of the environmental impact of VOCs.

1.3.2.4.2. Sucrose Esters as Reactive Diluent for Alkyd System Sucrose is a naturally occurring polyol consisting of eight hydroxyls (three primary and five secondary) on the core of two oxygen-linked cyclic ether rings (five- and six-member). Fatty-acid-substituted sucrose was explored in the 1960s as a coating resin, but obtaining a high degree of substitution of fatty acids on the sucrose proved to be challenging (55). A new process for esterifying sucrose with soybean oil fatty acids to achieve a high degree of esterification was developed by Procter & Gamble (P&G) Chemicals (55, 56). The sucrose esters of soybean oil fatty acids obtained had a high average degree of substitution of at least 7.7 of the 8 available hydroxyl groups (55). Its structure is shown in Figure 11. The utilization of sucrose ester as a coating resin is getting more popular due to its wide arbitrary hydrophilicity, excellent physical properties, surface activity, low toxicity level, and flexibility. Furthermore, it’s abundant and renewable supply and the low cost of the raw materials, i.e., sucrose and soybean oil, are some of the advantages over petrol-based chemicals. Sucrose esters of soybean oil (sucrose soyates) are the most attractive and promising sucrose esters owing to the fact that soybean oil is the most economic and readily available plant oil around the globe, as well as the fact that the US is the top soy producer (17, 55–58). Sucrose esters of soybean oils are superior to soybean oils since the functionality is much greater while retaining a very low viscosity. The average number of double bonds on soybean oil is 4.5 whereas the average number of double bonds on sucrose soyate approaches 12 (57). Along with the high functionality, the sucrose core functions as hard segments which offer rigidity and helps overcome some of the plasticization effects arising from the dangling chains of soybean oils (17, 55–58). Because of the low viscosities of sucrose esters (300-400 mPa·s), alkyd coatings formulated by using sucrose esters as reactive diluents have less than half the VOCs of traditional solvent-borne alkyd coatings. In 2009, P&G Chemicals and Cook Composites and Polymers (CCP) jointly received the Presidential Green Chemistry Award from the U.S. Environmental Protection Agency (EPA) based on this technology (55, 56).

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Figure 9. Synthesis of conjugated soybean oil from soybean oil (52, 54). (Adapted with permission from reference (52) and (54). Copyright 2014 John Wiley and Sons, and 2011 Springer.).

Figure 10. Synthesis of soya-based reactive diluents

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Figure 11. Structure of sucrose esters of soybean oils

1.3.3. Soya-Based Epoxy Coatings Epoxy resin formation with epoxidized soybean oils (ESOs) and fatty acids has been the most frequently studied polymerization involving soybean oils and their derivatives in recent years. Epoxidation is one of the most important and useful modifications using the double bonds of unsaturated fatty compounds, since epoxides are reactive intermediates that readily generate new functional groups. ESOs have been widely utilized to synthesize oil-based cationic and free-radical UV curable coating resins, i.e., AESO, by reacting acrylic acids with ESOs (8, 9, 21, 22). However, ESO-based coatings suffer from lower Tg value and a higher coefficient of thermal expansion, which was attributed to a lower degrees of epoxidation compared to some other epoxidized oils, i.e., linseed oil and castor oil (56, 57). The epoxidation reaction of sucrose soyate resin to produce epoxidized sucrose soyate (ESS) has shown to be an extremely promising route to overcome the drawbacks of ESO-based coatings and create high-performance, bio-based thermoset resins (55–58). ESSs have been used as resins for cationic UV-curable coatings. The epoxy anhydride curing of ESSs has been studied, and it demonstrated that ESS-based thermosets have exceptional performance (55–58). Crosslinking reactions involving epoxy homopolymerization of 100% biobased ESSs were studied and the resulting coatings properties were compared 222 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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against ESO and petrochemical-based soybean fatty acid ester resins. The low viscosity of ESS resins contributed to minimal VOCs for the resulting formulations. ESSs were found to have superior coatings properties, compared to ESO and the petrochemical-based soybean esters, which might be due to a higher Tg and a higher modulus of ESSs. The rigid sucrose core on ESSs provided an increase in coating performance when compared to coatings from epoxidized resins synthesized with tripentaeryithritol (TPE) as a core (57). ESSs were cross-linked with a liquid cycloaliphatic anhydride to prepare polyester thermosets. Compared with ESO, the ESSs-based thermosets have high modulus and are hard and ductile, high-performance thermoset materials while maintaining a high biobased content (71-77 wt%). The exceptional performance of the ESSs is attributed to the unique structure of ESS which has well-defined compact structures with high epoxide functionality (55). A novel 100% bio-based thermosetting coating system was developed from ESS with bio-based dicarboxylic acids. The resulting coating systems have good adhesion to metal substrates and perform well under chemical and physical stress. The hardness of the coating system was shown to be dependent on the chain length of the diacid used, lending itself to tenability (58). Biobased epoxy resins were also prepared by dipentaerythritol (DPE), tripentaerythritol (TPE), and ESS, and the impact of structure and functionality of the core polyol on the properties of the macromolecular resins and their epoxy-anhydride thermosets was explored. It was revealed that the sucrose-based thermosets exhibited the highest modulus, having the most rigid and ductile performance while maintaining the highest biobased content. DPE/TPE-based thermosets showed modestly better thermosetting performance than the ESO thermoset which showed worst performances (56). Epoxidation of sucrose esters followed by acrylation with acrylic acid leads to acrylated epoxidized sucrose soyate (AESS), which could also be cured by means of UV irradiation. Several coatings formulations with different degree of AESS and various reactive diluents were prepared and their coatings were shown to have excellent chemical resistance. Sucrose-based highly functional epoxy fatty compounds appear to be an attractive technology to overcome the traditional deficiencies of soybean oil-based materials, since thermosets made from these epoxy compounds exhibit high modulus, hard, and ductile thermosetting properties while maintaining a high biobased content.

1.3.4. Soya-Based Polyurethane Coatings Polyurethanes are a class of polymers with an extremely versatile range of properties and applications. Soybean oil has on an average about 4.5 double bonds per molecule. The unsaturated double bonds in soybean oils make possible various reactions, in order to obtain biobased polyols, enabling reactions with diisocyanates to get polyurethanes. It has been already shown that polyurethanes produced from soybean oils present some excellent properties such as enhanced 223 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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hydrolytic and thermal stability (17, 59, 60). Their structure can be tailored to suit specific requirements by selecting the type of polyols and isocyanates. There are various chemistry routes to functionalize soybean oils, epoxidation followed by ring opening reaction is one of the most common methods. Ring opening of epoxy groups can be achieved with alcohols or water in the presence of acid catalysts, with organic acids, inorganic acids, and by hydrogenation (Figure 12) (17). Thus, one or more alcohol functions could be added onto the fatty acid aliphatic chain. Currently the most commonly used method to ESO is based on peracetic acid formed in situ from the reaction between acetic acid and hydrogen peroxide at 60 °C in toluene for a duration of 12 h.

Figure 12. Synthetic routes from epoxidized oils to polyols (17). (Adapted with permission from reference (17). Copyright 2012 Taylor & Francis.).

224 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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To simplify the epoxidation/polyol formation procedure, some companies have converted soybean oils directly to soy polyols using a one-step reaction with hydrogen peroxide and formic or acetic acid. These are the same conditions commonly used to ESOs, but the solution is heated to allow the carboxylic acid present to open the epoxy groups formed. Although the obtained polyol has lower functionality (1.9-3.2 hydroxyl groups per triglyceride), the economic advantages and simplicity of this procedure make it very attractive (59). These polyols were reacted with different isocyanates confirming the expected correlation between Tg, crosslinking and OH functionality of the polyols. All ring-opened polyols have few or no double bonds and are therefore very stable and resistant to oxidation. The price for that is higher viscosity compared to petrochemical polyols due to higher rigidity of the hydrocarbon chains compared to polyether chains. While soybean oils have viscosity about 60 mPa.s, ESO has a viscosity around 220 mPa.s, and the corresponding polyol has a viscosity ranging from 5000 to 10,000 mPa.s, depending on the number of OH groups and the degree of oligomerization (60). Soybean oil-based polyols have an important place in the polyurethanes industry. Even if there are challenges for the chemical conversion during the whole manufacture process, the use of soybean oils to build the polyols structure still creates an opportunity for a long term sustainable source of polyurethane production. High-functionality polyols for application in polyurethanes were prepared by epoxide ring-opening reactions from ESS (61). The thermosets were prepared by using aliphatic polyisocyanates based on isophorone diisocyanate and hexamethylene diisocyanate. Compared to a soy triglyceride polyol, sucrose soyate polyols provide greater hardness and range of cross-link density to polyurethane thermosets because of the unique structure of sucrose soyate polyol which has compact structures with a rigid sucrose core coupled with high hydroxyl group functionality. The hardness-softness balance could be adjusted by tailoring the NCO/OH ratio and the type of isocyanate used. Sucrose soyate polyols are very tunable to generate polyurethane thermosets with a broad range of crosslink densities due to the high hydroxyl group functionality.

1.3.5. Soya-Based Coatings via Thiol-ene Chemistry Thiol-ene chemistry has been developed that enables rapid photopolymerization through a unique step-growth polymerization mechanism, during which ambient oxygen can be turned into a reactive species, as illustrated in Figure 13 (62). Thus, thiol-ene photochemistry has the advantage of insensitivity to oxygen inhibition. Thiol-ene photochemistry imparts the resultant polymers with excellent mechanical and physical properties. Furthermore, the extraordinarily high refractive index of thiol-ene materials enable high value-added applications such as coatings for optical lenses and fibers, and as adhesives for photonic and electronic components. Due to those merits, thiol-ene photochemistry has attracted extensive research interest in recent years. 225 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Figure 13. Illustration of free radical step-growth polymerization and oxygen scavenging mechanism of thiol-ene photopolymerization (62, 63). (Adapted with permission from reference (62) and (63). Copyright 2010 Springer, and 2004 John Wiley and Sons.).

It is highly desirable to incorporate bio-renewable materials, i.e., soybean oils, into the “green” UV-curable technologies. Such a combination provides a “green+green” solution to the stricter environmental regulations that the coating industry is facing. The incorporation of soybean oils into thiol-ene-based materials is expected to provide bio-renewable, UV-curable, low cost materials with interesting properties and little or no environmental impact. The double bonds in soybean oils have already been functionalized via thiol-ene ‘click’ chemistry to afford a family of renewable monomers. Webster and co-workers synthesized novel soya-based thiols and enes via BF3-catalyzed ring opening reaction of ESO by appropriate thiols and alcohols, respectively (Figure 14) (62). The soya-based thiols and enes were formulated with petrochemical based enes and thiols, respectively, to make thiol-ene UV-curable coatings. It has been shown that soya-based thiols and enes with higher functionality can be UV-cured in combination with petrochemical-based enes or thiols even without the presence of free radical photoinitiators. It was also shown that better coating material properties could be obtained by the addition of multifunctional, hyperbranched acrylates which could improve the Tg and tackfree of the coating formulation. A novel approach was reported to obtain soya-based thiol oligomers through a direct, low-cost synthetic route (64). The synthesized soya-thiols can be used to formulate soya-thiol-ene UV curable materials and soya-thiourethane 100% solid thermal curable materials (Figure 15). The effect of several reaction conditions, including thiol concentration, catalyst loading level, reaction time, and atmosphere, on the molecular weight and the conversion to the resultant soya-thiols were examined. High thiol functionality and concentration, high thermal free radical catalyst concentration, long reaction time, and the use of a nitrogen reaction atmosphere were found to favor fast consumption of the soybean oil, and produced high molecular weight products. The synthesized soya-thiol oligomers could be used for renewable thiol-ene UV curable materials and high molecular solids and thiourethane thermal cure materials.

226 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Figure 14. Synthesis of thiol and ene functionalized ESO through reaction of epoxy ring opening by multifunctional thiols and hydroxyl functional enes (62).

Figure 15. Thermal free radical initiated thiol-ene reaction between thiols and vegetable oil (64). (Adapted with permission from reference (64). Copyright 2011 John Wiley and Sons.).

Bio-based thiols were also synthesized via the thermal thiol-ene reactions between sucrose soya and multifunctional thiols (65). Thermoset thiourethane coatings were prepared from these thiol oligomers and polyisocyanate trimer resins. Generally, all the coatings showed good adhesion to aluminum panels, and had high gloss. Coatings based on more rigid isophorone diisocyanate (IPDI)-based polyisocyanate showed higher Tg, hardness and direct impact resistance compared with the hexamethylene-diisocyanate (HDI) based polyisocyanate counterparts. ESS-based, thiol-functionalized oligomers were prepared from ESS and bio-(mercaptanized soybean oil (MSO) and di-pentene dimercaptan (DD)) or petro-based multifunctional thiols via a thermally initiated thiol-ene reactions. Thermoset thiourethane coatings were then formulated from these thiol oligomers and HDI trimer and IPDI trimmers. MSO-based coatings showed higher thermal stability than DD-based ones, which indicates that the higher functionality and more branched structure had a great impact on the thermal stability of these coatings (65). 227 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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1.3.6. Soya-Based Organic-Inorganic Hybrid Coatings

Organic-inorganic hybrid coatings have received much attention during the past 20 years. Organic-inorganic coatings provide improved abrasion resistance, chemical resistance, adhesion, and mechanical properties. In general, the organic matrix is the continuous phase in creamer materials and the inorganic matrix is the continuous phase. The resulting materials provide a combination of physical properties found in both ceramic and polymeric materials by producing a homogenous material with both organic and inorganic characteristics at low cure temperatures. Soucek and coworkers developed several soya-based organic-inorganic coatings (66–70). The organic-inorganic coatings based on ESO with sol-gel precursors can be depicted as the model shown in Figure 16 (66). The continuous phase is the organic phase, and the discontinuous phase is the inorganic phase. The primary interest in the development of these coatings was to reintroduce soybean oils as a renewable resource for coating applications. Their research showed that the sol-gel technique of alkoxysilanes is one of the useful methods to prepare organic-inorganic hybrid materials. The advantage of the sol-gel technique is that the reaction proceeds at ambient temperature to form ceramic materials compared to the traditional methods at high temperature. The addition of sol-gel precursor had a considerable influence on the corrosion inhibition and adhesion of coatings. The resulting ceramer coatings exhibited improved mechanical properties, enhanced adhesion to Al substrates and good corrosion resistance properties compared to the parent soybean oil coatings and were developed for aircraft and aerospace protective coatings. It was observed by the same group that the ESO-based ceramer dried faster than the blown soybean oil-based ceramer coatings at the same sol-gel precursor loading. It was speculated that the sol-gel precursors were presumably more reactive toward the ESO (11, 66–70).

2. Soya-Based Adhesives Soy protein-based adhesives have been considered for applications in composites for a century (4, 71, 72). Soybean oil-based pressure sensitive adhesives (PSAs) have been used recently for the replacement of petroleum-based adhesives. Wood industry needs environment-friendly adhesives from renewable resources because petroleum resources are finite and are becoming limited, whereas the demand for adhesives is increasing. Carcinogenic formaldehyde-based adhesives pose threat to human health (73–75). On the other hand, abundant soy proteins are available from renewable resources and agricultural processing by-products. 228 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Figure 16. Ceramer model (66). (Reproduced with permission from reference (66). Copyright 2000 Springer.). 2.1. Soy Protein-Based Adhesives 2.1.1. Adhesives for Wood Composites Wood composites are uniform boards or lumbers from forest products bonded with adhesives. Commonly used wood composites include plywood, particleboard, oriented strand board (OSB), medium density fiberboard (MDF), and composite lumber products, i.e., laminated veneer lumber (LVL), glued laminated lumber (glulam), and I-joist. Wood adhesives are essential components of wood composites. Until the 20th century, wood adhesives had been obtained from natural materials, such as hooves, hides, milk, and soybeans (76). However, in the early 20th century, researchers found that urea-formaldehyde (UF) adhesives made superior interior products compared to bio-based ones, and phenol-formaldehyde (PF) adhesives made excellent exterior products (2, 77, 78). Durability and favorable economics, driven by the expansion of the petrochemical industry, led to the expansion of reconstituted wood products using synthetic adhesives into a wide variety of building construction materials and interior wood products to replace solid wood. At present, the adhesives used for production of wood composites are mainly formaldehyde-based and petrochemical-based, such as PF and UF resins, and isocyanates. In North America, formaldehyde-based adhesives accounted for over 90 % of the total adhesive consumption in recent years, indicating that formaldehyde-based adhesives plays a dominant role in the wood adhesive market (71). 229 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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However, formaldehyde-based adhesives are not environmentally friendly products. Formaldehyde is emitted in the production and use of wood composites with UF or PF resins, posing a great hazard to human health. When its concentration in air is near to 120 mg/m3, formaldehyde will cause various symptoms such as eye irritation, nose and throat irritation, and headaches (79). Based on extensive investigation, International Agency for Research on Cancer, a division of World Health Organization, reclassified formaldehyde as a human carcinogen in June of 2004 (80). California Air Resource Board (CARB) passed a tough regulation on limiting formaldehyde emission from wood composite panel products sold and used in California in 2007. A national regulation of limiting formaldehyde emission, “formaldehyde standards for composite wood products act,” was signed into law in July 2010 (77). Moreover, formaldehyde-based adhesives are based on non-renewable petrochemicals. Finite oil reserves, tightened environmental regulations on the emission of volatile organic compounds in the production, and expanding use of wood composites have generated pressure on the forest products industry to develop more environmentally friendly wood adhesives (2, 81). The most desirable way of resolving these issues is to use formaldehyde-free adhesives from renewable resources.

2.1.2. Soy Protein as an Adhesive At present, soybean meal is mainly used as animal feed. Only a small portion of soybean meal is currently used in non-food industrial applications such as surfactants, inks, fuels and lubricants (4, 82). Soybean consists of about 40 wt% protein, 34 wt% carbohydrate, 21 wt% fat, and 4.9 wt% ash. It can be processed to produce various soybean products (83, 84). The processing of Soybean seeds includes cleaning, drying, cracking, dehulling, flaking and extraction of oil by using hexane (Figure 17) (85, 86). After the removal of soybean oil, the resulting powder is called defatted soybean meal or soy flour (40-55 wt% protein). The defatted soybean meal can be further processed to produce soy protein concentrate (SPC) and soy protein isolate (SPI) through the partial removal of carbohydrates. The protein content for these two products is about 70 wt% for SPC and 90 wt% for SPI (83, 86).

Figure 17. Flow diagram for the production of defatted soybean meal (86). (Adapted with permission from reference (86). Copyright 2002 Elsevier.). 230 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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The major components of soy protein are shown in Table 2 (87). The storage proteins 11S and 7 S are the principal components of soy protein (S stands for Svedberg units). The 11S fraction consists of glycinin which is the principal protein of soybeans. Glycinin has a molecular mass of 320-360 kDa. The 7S fraction is highly heterogeneous. Its principal component is beta-conglycinin with a molecular mass in the order of 150-190 kDa. (86). The two components 11S and 7S are composed of a combination of about 20 different amino acids. Each amino acid is known to have functional groups attached to the side polypeptide chains of the protein molecule. These functional groups, including OH, COOH, NH3, are available for various chemical modifications that could alter the microstructure of soy protein and considerably affect its chemical and mechanical properties (84, 88). Those features render proteins to be the key adhesive components. Soy protein in the form of soy flour is abundant, inexpensive, and renewable. Soy protein is used mainly for animal feed and food applications. One market with significant volume potential for soy protein is wood adhesives. Wood adhesives are potentially a huge market for the oversupplied soybean (89–91).

Table 2. The comparison of fractions in soy protein (87). SOURCE: Reproduced with permission from reference (87). Copyright 1979 Springer.

The use of soy protein as an adhesive could be traced back to ancient times, although its first commercial use as a wood adhesive for the production of plywood did not begin until the 1930s. Soy protein-based adhesives were widely used for the production of wood composites especially plywood in the United States from 1930s to 1960s. As a wood adhesive, soy protein has many unique features such as low cost, ease of handling, low press temperatures, and the ability to bind wood with relatively high moisture content (71, 92). However, wood composites bonded with soy protein-based adhesives have also have some drawbacks such as lower strengths and lower water resistance than wood composites bonded with synthetic UF and PF resins (4, 72–74). At present, soy protein-based adhesives have a very insignificant share in the wood adhesive market, and virtually been replaced by synthetic adhesives such as formaldehyde-based adhesives. However, soy protein represents an attractive raw material for the bonding of wood if a technique can be developed to improve the strength and water resistance of soy protein-based adhesives (71). There has been a resurgence of interest in the development of soya-based wood adhesives in the last two decades, because those adhesives can be cost competitive and more environmentally acceptable, especially with the emphasis 231 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

on reduced formaldehyde emissions (2, 4). Various new methods have been investigated for improving the strength and water resistance of wood composite panels bonded with soya-based adhesives.

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2.1.3. Soy Protein-Based Adhesives for Wood Composites Extensive research has been done in an efforts of developing soya-based wood adhesives. To reduce the relative ratio of synthetic adhesives, soy flour is used as an ingredient in the currently used synthetic adhesive to make a hybrid adhesive. Addition of soy flour to PF or phenol-resorcinol formaldehyde (PRF) adhesives to provide hybrid adhesives has been extensively studied (93, 94). A soybean/PF resin based adhesive with 70% soya-based adhesive and 30% PF resin was used in plywood, the bonding strength of which meets the requirements of the type II plywood and the emission level of which reaches E0 formaldehyde emission. Blends of soy protein and phenolic resins was developed and used for finger jointing of green lumber that cured rapidly at room temperature and had excellent water resistance and reduced formaldehyde emissions. As much as 70% of PF can be replaced by soy protein based adhesive with comparable physical properties for oriented and random strandboard (95). The soya-based adhesive has also been mixed with melamine urea formaldehyde resin (MUF) and was found to enhance water resistance and wet-shear strength (96). It demonstrated that the addition of soy adhesive system significantly reduces formaldehyde release from plywood. Based on the results, the optimum amount of the soy addition depends on the requirements of use of the final product and formaldehyde emission. The highest substitution level recommended is 25% for the production of panels with very low formaldehyde emission for use in class 2 or 3 conditions, whereas up to 75% substitution would seem possible for class 1 panels. The compatibility of a modified soy protein with commercial synthetic adhesives (UF based resin, dichloromethane based resin, toluene based resin, and PVA based resin) was also investigated (97). Four different blending ratios of soya-based adhesives and synthetic adhesives were studied. It was shown that soya-based adhesives can be modified into functional copolymers that interact and react with commercial synthetic adhesives to enhance adhesion performance. Apparent viscosity of blends was reduced significantly at 20-60% synthetic adhesives, which improved flowability and spread rate. It was found that dry adhesion strength of soya-based adhesives, synthetic adhesives, and their blends were all similar with 100% wood cohesive failure. Water resistance of all synthetic adhesives was improved by blending with soya-based adhesives in terms of the wet adhesion strength. Epoxy resin (EPR) and melamine-formaldehyde (MF) were mixed with soya-based adhesive to improve the water resistance of the resulting adhesives for wood panels (78). The results indicated that the two resins improved the water resistance of soya-based adhesive and the hybrid EPR+MF, was the best. Type II and even type I plywood could be prepared when 6.4%EPR+6.4%MF is used. FT-IR indicated that the great improvement of water resistance of soya-based 232 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

adhesive modified with EPR and MF might be caused by the reaction between epoxy and -OH, and that between MF and -NH. The partial substitution of formaldehyde based adhesives with soya-based ones could be an intermediate solution for the manufacture of wood composites, and could contribute to very low formaldehyde emissions.

2.1.4. Chemical Modification of Soy Protein for Adhesive Application

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2.1.4.1. Adhesives from Denatured Soybean To promote reaction with synthetic polymers, soy protein must be unfolded to expose its functional groups. It was hypothesized that unfolded soy protein may act as a copolymer, reacting with various synthetic resins to enhance adhesion performance and reduce emissions of VOCs. Thus, different chemicals and enzymes have been used to denature soybean protein and then the denatured soybean proteins are used as wood adhesives. Various hydrolysis methods have been used to unfold soy proteins. Alkali-modified soya-based adhesives were reported to be stronger and more water resistant compared with adhesive containing unmodified soy protein (98, 99). Alkaline treatment helps in unfolding the protein molecules and exposing the polar groups for interaction. It was demonstrated that the treatment of soybean protein with protease enzymes significantly improved the strength and water resistance of plywood samples bonded with the modified soy proteins. The effect of varying concentrations of urea and guanidine hydrochloride on adhesion property of modified-SPI adhesives was investigated by Huang and Sun (100). Soy protein modified by urea showed greater shear strengths in comparison to unmodified SPI. In the case of guanidine hydrochloride-treated SPI, the isolate treated with guanidine hydrochloride gave greater shear strength than unmodified SPI. The treatments of soy protein with sodium dodecyl sulfate (SDS) were also found to improve the strength and water resistance of the resulting plywood panels (101). Compared with urea and guanidine hydrochloride, SDS-modified SPI have increased water resistance, as well as improved adhesive strength. The techniques for denaturing defatted soy flour by a combination of acid, salt and alkali as a modifier for soya-based adhesives were investigated to improve the water resistance of soya-based adhesives (102). The FTIR and XPS spectra illustrated the change of chemical groups and conversion of the protonized products: the amide link hydrolysis and decarboxylation have taken place when defatted soy flour was denaturized by acid and salt with the active groups, -NH2, -COOH and -OH, increased. The alkali modification caused some aminolysis with the active groups increased further. Curing of the soya-based adhesives made amide links reestablished and hence caused amination, resulting in the improvement of crosslink of soya-protein and water resistance. The adhesion of soya-based adhesives depends on, to a large extent, the ability of protein to disperse in water and the availability of polar side group to interact with wood. The treatment of soybean protein with denaturants 233 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

unfolds the protein molecules, thus increasing the dispersion of protein and the availability of those polar groups that are buried inside protein molecules in the native proteins (4). It imparts the modified soybean proteins with higher hydrophobicity and thus enhances their water resistant properties. Therefore the adhesive strength is increased (4). However, the overall performance of these denatured soybean-based adhesives is still not comparable with synthetic resins such as UF and PF.

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2.1.4.2. Adhesives from Crosslinking Modifications Crosslinking modification is a common method for the modification of soyabased adhesive. Since there are many reactive groups in soy proteins, such as -OH, -SH, -COOH, and -NH2, many chemicals could be used for the crosslinking. Polyamines are the most commonly used curing agents for soya-based wood adhesives (103). A novel adhesive based on soy protein isolate (SPI), maleic anhydride (MA), and polyethyleneimine (PEI) has been developed (71). Wood composites bonded with MA-SPI-PEI adhesives were comparable to those bonded with commercial PF resins in terms of the shear strength and water resistance. When the modified adhesive was applied to particleboard manufacturing, the properties, i.e., internal bond, modulus of rupture, modulus of elasticity, of the particleboard met the minimum industrial requirements of M-2 particleboard (74). MA first reacted with hydroxyl groups and amino groups of SPI to form ester-linked maleyl groups and amide-linked maleyl groups on SPI. The reactions between those maleyl groups with amino groups of PEI formed highly crosslinked adhesive networks during the hot-press which promoted the curing of the adhesives. The investigation of the curing mechanisms of the MA-SPI-PEI adhesives revealed that amino groups of PEIs reacted with maleyl esters to form maleyl amides and also reacted with the C=C bonds of maleyl groups via Michael addition reaction in the cure of MA-SPI-PEI adhesives. The reactions between PEI and MA-SPI at elevated temperature are proposed in Figure 18. It has been well documented that an amine can readily react with an ester to form an amide. The reaction products, such as I and II shown in Figure 18, may further react with themselves to form oligomers (71).

Figure 18. Proposed reactions in the modification of SPI with MA, and between MA-SPI and PEI (71). (Adapted with permission from reference (71). Copyright 2007 Elsevier.). 234 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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However, the above modified adhesive is not practical for commercial application because SPI and PEI are too expensive to be used as a raw material for making wood adhesives. PEI is from a petrochemical source, thus not renewable and environmentally-friendly. In addition, the long reaction time and elevated temperature in modifying SPI and the time-consuming process of drying modified SPI contribute to other drawbacks of the SPI-MA-PEI adhesive. Soy flour (SF), an abundant and inexpensive form of soybean protein product, has been used as an alternative to SPI for the production of soya-based adhesives. SF-PEI-MA adhesive for plywood has been reported in the literature (4). The optimum formulation of this adhesive and the optimum hot-press conditions for making plywood were investigated. Results showed that the SF/PEI/MA weight ratio of 7/1.0/0.32 resulted in the highest water resistance. Plywood panels bonded with this SF-PEI-MA adhesive exceeded the requirements for interior applications. It was proposed that MA first reacted with PEI to form amide-linked maleyl groups that further reacted with amino groups in SF and PEI during a hot-press of making plywood panels (Figure 19). The PEI-MA adduct might coat or bundle water-soluble carbohydrates, thus minimizing their negative effects on the water resistance. Hydroxyl groups of the carbohydrates might also react with the PEI-MA adduct via Michael addition although hydroxyl groups are weaker nucleophiles than amino groups, thus further reducing the negative effects of water-soluble carbohydrates on the water resistance.

Figure 19. Proposed curing reactions of SF/PEI/MA adhesives (4). (Adapted with permission from reference (4). Copyright 2007 Springer.).

In this SF-PEI-MA adhesive, PEI is still too expensive to allow the immediate commercial application of this adhesive for making interior plywood. In addition, PEI is currently made from petrochemicals. Development of a polyamine from renewable materials for replacing PEI is desired. Chemical modifications of soy protein using mussel adhesive protein as a model have been demonstrated to be 235 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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effective ways of converting soybean protein to a strong and water resistant wood adhesive. The adhesive protein secreted by mussels is an excellent example of the renewable formaldehyde-free adhesive (104, 105). To withstand turbulent tide and wave, mussels are anchored to rocks through a strong and water resistant proteinaceous byssus. The portion of byssus that attaches to rock is called an attachment plaque (106, 107). The protein in the attachment plaque is commonly called marine adhesive protein (MAP) (72). MAPs are strong and water resistant adhesives, but are expensive and not readily available. A catechol group is one of the key functional groups found in MAPs. The dopamine-modified SPI had the same catechol functional group as MAP. Dopamine was successfully grafted onto soy protein isolate (SPI) via amide linkages (108). Imparting the catechol group to soy protein could transform the soy protein to a strong and water resistant adhesive. It was found that the strength and water resistance of the wood composites bonded with the modified SPIs depended on the amount of the catechol group in the modified SPIs. The adhesive strengths and water resistance of plywood samples bonded with dopamine-modified SPI are comparable to those bonded with commercial PF and UF resins (108). Preparation of dopamine-modified SPI is shown in Figure 20. Protection of phenolic hydroxyl groups in chemical A with dichiorodiphenylmethane could generate chemical B. Treatment of SPI with B in the presence of 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide hydrochloride (EDC) readily gives rise to chemical C (the amino group in B reacted with carboxylic acid groups in SPI to form amide linkages). Deprotection of chemical C readily provided chemical D (dopamine-modified SPI) (108).

Figure 20. Preparation of dopamine-grafted soy protein isolate (108). (Adapted with permission from reference (108). Copyright 2002 John Wiley and Sons.).

Mussel protein contains a high amount of mercapto containing cysteine. It was revealed that increasing the free mercapto group content in soy protein could greatly increase the strength and water resistance of wood composites bonded with the modified soy protein (72). A free -SH group, another key functional group from the MAPs, was successfully introduced to the soy protein via covalent linkages (72). For the synthesis procedure, acetylation of the -SH group in chemical A provides S-acetylcysteamine (chemical B) (Figure 21). The amino group in chemical 236 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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B reacts with the free carboxylic acid groups in the SPI in the presence of EDC provides S-acetylcysteamine-modified SPI (chemical C). The treatment of chemical C with a NaOH solution removes the acetyl group to yield cysteamine-modified SPI (chemical D). Increasing the content of the -SH group significantly increased the strength and water resistance of wood composites bonded with the modified soy protein. It was proposed that the formation of disulfide bonds between SH group as well as a Michael addition reaction between -SH group and quinones could account for the increased strength and water resistance. It was also proposed that the -SH groups in a protein could easily get oxidized to form disulfide bonds, thus crosslinking the protein to form a three dimensional network (109, 110). The -SH group could also react with quinones through a Michael addition reaction (111).

Figure 21. Preparation of modified SPIs (72). (Adapted with permission from reference (72). Copyright 2004 John Wiley and Sons.). Commercialization of soy adhesives was limited until suitable technology and market drivers existed. The innovative work of Oregon State University led to the use of a crosslinker for providing acceptable water resistance for interior wood products bonded with soya-based adhesives. This environmentally friendly adhesive is stronger than and cost-competitive with conventional adhesives such as UF and PF adhesive (2). This soya-based adhesive mainly consists of soy flour and a small amount of a curing agent, polyamidoamine-epichlorohydrin (PAE) resin (2). This PAE resin has been found to be an excellent curing agent for soybean protein. In collaborative work with private industry, this strong, environmentally friendly, cost-competitive soya-based adhesive was used successfully to replace toxic UF resin in commercial production of wood composite panels, such as plywood and particleboard since 2004. Major reactions in the cure of SPI-PAE adhesives are proposed in Figure 22. First, the azetidium group in PAE resins reacts with the remaining secondary amines in the PAE resin, thus causing crosslinking (reaction A in Figure 22). Second, the azetidium group may also react with carboxylic acid groups such as those of glutamic acid and aspartic acid in SPI (reaction B in Figure 22). Third, various amino groups in SPI can also react with the azetidium group (reaction C 237 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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in Figure 22). All these reactions result in a water-insoluble three-dimensional network.

Figure 22. Proposed curing mechanism for SPI-PAE adhesives (2). (Adapted with permission from reference (2). Copyright 2004 Springer.).

2.1.4.3. Biobased Curing Agent for Soya-Based Adhesives The PAE resin is derived from petrochemicals and is the most expensive component of this soya-based adhesive. Some studies are going on aiming at development of new curing agents from renewable and cost-effective source. Epichlorohydrin (ECH) and ammonium hydroxide have been evaluated as a replacement of PAE (76, 77). ECH can be derived from glycerol, which is a byproduct from biodiesel production. NH4OH is synthesized from hydrogen and nitrogen. Consequently, the curing agents based on ECH and NH4OH are independent from petrochemicals. Preparation of this curing agents and proposed curing reactions are shown in Figure 23. It has been demonstrated that chlorohydrins and azetidinium groups could effectively react with amino groups, carboxylic acid group, and other nucleophilic groups in soy protein, thus effectively crosslinking soy protein. The structure of the final product of in Figure 23 illustrated proposed reaction products between a chlorohydrin/azetidinium with an amino group in soy flour. Water resistance tests showed that plywood panels bonded with this adhesive met the requirements of interior plywood. The water resistance performances of SF-based Plywood made with this curing agent is comparable with that made with PAE (76).

238 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Figure 23. Preparation of a curing agent and proposed curing reactions with soy flour (CA stands for curing agents) (77). (Adapted with permission from reference (77). Copyright 2011 Elsevier.).

A wet method and dry method of applying this adhesive onto wood flakes were evaluated for making randomly oriented strand board (R-OSB) and OSB (73). OSBs made with the SF-curing agent adhesive had strengths higher than or comparable to commercial OSBs. It demonstrates that this formaldehyde-free, environmentally friendly adhesive can potentially be used to replace PF and isocyanates for production of OSB panels with superior strength properties. The dry method allows the strengths of R-OSB panels to meet the minimum industrial requirements at a higher SF:curing agent weight ratio than the wet method. The dry method is superior to the wet method in terms of reducing the adhesive cost. However, this adhesive could not be easily sprayed onto wood particles for making particleboard because of its high viscosity. Thus a new method of using the original recipe of the soya-based adhesive used in plywood and OSB production for making particleboard was developed (75). In this method, SF was first mixed with water to form dilute soy slurry that was easily coated onto wood particles. The soycoated wood particles were dried to certain moisture content and then further coated with an aqueous curing agent. With this new method, the SF-curing agent adhesive can be successfully used for production of particleboard panels, which offers an alternative way of using this formaldehyde-free soya-based adhesive for making particleboard. The internal bond, modulus of rupture, and modulus of elasticity all exceeded the industry requirements for the M-2 particleboard. In view of sustainable development and environmental protection, renewable itaconic acid was used to synthesize another bio-based curing agent, i.e., itaconic acid-based PAE resin (IA-PAE) for soya-based adhesives (90). The synthesis process and possible structures of IA-PAE are shown in Figure 24.

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Figure 24. Synthesis process of itaconic acid-based PAE resin (90). (Adapted with permission from reference (90). Copyright 2013 Elsevier.).

Both N-(3-chloro-2-hydroxypropyl) groups and azetidinium rings of IA-PAE could perform as functional groups in IA-PAE modified soy flour adhesive (IA-PAE-SF). Wet strength and water resistance of IA-PAE-SF on plywood were comparable to that of commercial PAE-SF. Crosslinking networks were formed during hot-pressing process and thus improved water resistance of IA-PAE-SF on plywood. Characterization of water-insoluble solid content of cured adhesives and observation of SEM confirmed the formation of crosslinking networks in cured IA-PAE-SF. This crosslinking network should account for the improved water resistance of plywood bonded by IA-PAE-SF adhesive. All results showed that it is feasible to synthesize bio-based PAE using itaconic acid. Bio-based IA-PAE is expected to bring a sustainable development to soya-based adhesives. Chemical phosphorylation of SF (PSF) with phosphorus oxychloride (POCl3) as the phosphorylating agent significantly increased its wet bond strength (112). The increase in wet bond strength of PSF was mostly due to the phosphate groups incorporated into the proteins and carbohydrates. The attached phosphate groups acted as crosslinking agents, either via covalent esterification with hydroxyl groups on wood chips or via ionic and hydrogen-bonding interactions with functional groups in wood chips. At hot-press temperatures above 160 °C the wet bond strength of PSF could reach a level that might be acceptable for interior-used hardwood plywood and particleboard. 240 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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POCl3 is an economical and practical reagent for protein phosphorylation in a large-scale production. In this phosphorylation reaction, POCl3 reacts with amino groups and hydroxyl groups in proteins as shown in Figure 25. Because no organic solvents or petroleum-derived chemicals were used in the modification step, the method offers a green chemistry approach to produce plant protein-based wood adhesives.

Figure 25. Reaction of POCl3 with proteins (112). (Adapted with permission from reference (112). Copyright 2014 John Wiley and Sons.). 2.2. Soybean Oil-Based Pressure Sensitive Adhesives The current interest in cheap, biodegradable polymeric materials has encouraged the development of pressure sensitive adhesives (PSAs) from readily available, renewable inexpensive natural sources, such as carbohydrates, starch and proteins. The use of annually renewable resources and the biodegradability or recyclability of the product is becoming important design criteria. New environmental regulations, societal concerns, and a growing environmental awareness throughout the world have triggered the search for new opportunities for developing biodegradable PSA products.

2.2.1. Pressure Sensitive Adhesives PSAs are a distinct category of adhesives that are in a dry and solvent-free form, are aggressively and permanently tacky at room temperature, and can firmly adhere to a variety of surfaces upon mere contact with light pressure. They are viscoelastic materials combining a liquid-like dissipative character necessary to form molecular contact under a light pressure and a solid-like character to resist macroscopic stress during the debonding phase (113, 114). PSAs are very easy to use because they do not have to be activated or cured by heat or radiation. PSAs are widely used in tapes and labels, which can easily stick to numerous substrates such as metal, glass, plastics, and paper with a light pressure. There is no storage problem, and there is no mixing or activation necessary, no waiting is involved. Often the bond is readily reversible (115). More importantly, the uses of PSAs are very environmentally friendly because no organic solvents or chemicals are needed. However, the process for the preparation of PSAs may not be environmentally friendly. During the preparation, an organic solvent such as toluene has to be used to dissolve natural rubber so 241 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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that the natural rubber can be coated on films or paper for the production of tapes and labels (116). At present, commercially available PSAs are typically based on elastomers compounded with suitable tackifiers, plasticizers and waxes. The most commonly used elastomers are petrochemical based polymers such as acrylic copolymers, styrene-isoprene-styrene (SIS) block copolymers, styrene-butadiene-styrene (SBS) block copolymers, and ethylene-vinyl acetate copolymers (117). Most commercial PSA are still based on petroleum resources. Petroleum is non-renewable and thus not sustainable. Furthermore, most petrochemical-based polymers are not biodegradable, thus potentially producing environmental pollution. It is no wonder that the design of PSAs derived from renewable resources is currently attracting a lot of attention in several academic and industrial laboratories throughout the world. Soybean oils are one of the most important renewable resources with promise to replace petroleum chemicals. The long aliphatic chains of soybean oils impart unique properties to the resulting polymers such as elasticity, flexibility, ductility, high impact strength, hydrolytic stability, hydrophobicity, internally plasticizing effect and intrinsically low glass transition temperature (113). There are some reports describing the use of soybean oils or their derivatives for PSA applications.

2.2.1.1. AESO-Based PSAs Epoxidized soybean oil (ESO) is a well-known commercially available renewable resource. Epoxidation of soybean oils is inexpensive and efficient, with conversion rates of up to 98% because of their built-in double bonds (118). ESO were further reacted with acrylic acid to form acrylated ESO (AESO). The free radical polymerization of the AESO resulted in PSAs. Comonomers such as 1,4-butanediol diacrylate and methacrylate were needed for the improvement of the PSA performance (118–121). Copolymer derived from AESO and butyl methacrylate was studied for biodegradable medical PSA applications. The formulation consisting ESO resin and butyl methacrylate, 100:0.40, yields favourable properties of shear holding time and peel strength to qualify as PSA (115). The main challenge in commercializing these PSA technologies is longer curing time, which is not acceptable to industry. In addition, this class of PSAs still requires the substantial amount of (meth)acrylic acid and (meth)acrylates to facilitate crosslinks. Obviously, petrochemicals were still considerably used in this approach.

2.2.1.2. ESO-Based PSAs Sun et al. proposed an inspiring concept of renewable PSAs derived from ESO and dihydroxyl soybean oil (DSO) without using any petrochemicals (118, 122, 123). This PSA was prepared by reacting ESO with phosphoric acid and 242 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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formulating the resulting polymer with DSO which was derived from ESO and added as a tackifier (Figure 26). It was demonstrated that the PSAs had comparable peel strength with commercial PSAs. More interestingly, the resulting PSAs had excellent thermal stability, and exhibited transparency similar to glass.

Figure 26. Chemical structure of ESO, DSO, and copolymeric matrix of ESO PSA (118). (Adapted with permission from reference (118). Copyright 2011 American Chemical Society.).

It was proposed that phosphoric acid functions not only as a brønsted acid catalyst that activated the epoxide toward nucleophilic attack by the diol, thus generating ether (C-O-C) cross-linkages, but also as a reaction partner establishing phosphate ester linkages. It was shown that epoxides derived from soybean oils react with H3PO4 with a significant degree of phosphate ester-based cross-links (Figure 27) (124). It was also reported that phosphoric acids with diepoxides can generate not only phosphate ester cross-links but also ether cross-links (125). Phosphoric acid is a more eco-friendly catalyst than perchloric acid, which was used previously as a catalyst to open the oxirane rings of ESO for preparation of PSAs (123). ESO-based PSAs prepared with phosphoric acid had higher peel strength than ESO-based PSAs prepared with perchloric acid. The results show that soybean oil-based PSA films and tapes have great potential to replace petro-based PSAs for a broad range of applications including flexible electronics and medical devices because of their thermal stability, transparency, chemical resistance, and potential biodegradability from triglycerides (123). However, during preparation of the PSA Tapes, the mixtures of ESO and DSO were either dissolved in methyl acetate to obtain a dilute solution which is an organic solvent, or dissolved in H2O/tetrahydrofuran (THF) for synthesis of phosphate esters containing dihydroxyl soybean oils (PDSO). 243 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Figure 27. Synthetic scheme of the ESO PSA from ESO/PDSO (123).

Dimer fatty acid-based polyesters were also reported as a viable alternative for PSAs. The carboxylic acid-terminated polyesters from bulk polycondensation of dimerized fatty acids with several diols such as dimer fatty diol, butanediol or isosorbide is synthesized. The resulting polymers were cured with ESOs to form viscoelastic bioelastomers with tunable stickiness degrees (117). It was shown that in soft materials such as PSAs, isosorbide can play multiple roles such as adjusting the Tg, modulating the viscoelastic spectrum, and tuning the interfacial properties of the glue. Figure 28 shows the possible curing process. The curing could take place by addition esterification of the polyester carboxylic acids end-groups with the multifunctional epoxy crosslinker (path A), by ether formation between oxirane and hydroxyl groups (path B), and by condensation esterification between carboxylic acid and hydroxyl functionalities (path C). However, during the formulation, polyesters and ESO were homogenized with ethyl acetate which is an organic solvent.

2.2.1.3. 100% Bio-Based PSAs A new class of renewable PSAs designed and developed from soybean oil was reported. Soybean oil was epoxidized and hydrolysed selectively on the ester groups to afford a mixture of epoxidized fatty acids (EFAs) (Figure 29) (113). The EFA mixture without further purification was then polymerized directly in the presence and absence of a small amount of biobased dicarboxylic acid or 244 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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anhydrides such as dimer acid to afford hydroxyl-functionalized polymers. The polymers were suitable for PSA applications which were verified by the peel strength, loop tack, shear strength and viscoelastic properties. The resulting PSAs not only could be 100% fully bio-based and potentially biodegradable, but their preparation and application did not require the use of an organic solvent or a toxic chemical, thus being environmentally friendly. The properties of the resulting PSAs could be tailored for different applications such as tapes and labels through the selection of a dicarboxylic acid and its usage. A novel and simple approach for development of PSAs directly from ESO without the extra hydrolytic step was reported by the same group (114). ESO was polymerized and cross-linked with a dicarboxylic acid including dimer acid (DA), sebacic acid, and adipic acid, to generate superior PSAs. DA is a long-chain dicarboxylic acid derived from unsaturated fatty acids. As a monomer, DA can impart unique properties to the resulting polymers such as elasticity, flexibility, hydrolytic stability, hydrophobicity, and intrinsically low Tg. Theoretically, a mixture of ESO and DA would polymerize to form hydroxyl-functionalized polyesters via the ring-opening of the epoxy groups with the -COOH groups. ESO reacts with DA via the epoxy-COOH reaction to form hydroxylfunctionalized oligomeric chains at the beginning of the polymerization, the remaining epoxy groups of ESO can react with DA or -COOH containing oligomers to form branches. As the step-growth polymerization proceeds, the branches lead to formation of new oligomeric/polymeric chains that can lead to more branches, thus forming a three-dimensional network. Along with the consumption of the epoxy groups, the reaction mixture became viscous and eventually led to the formation of a gel at which cross-linked polymer networks form from the branched or highly branched oligomers and polymers. The adhesive properties of the PSAs can also be tailored for specific applications through the selection of the dicarboxylic acid and its usage.

Figure 28. Scheme of the possible curing pathways (117). (Adapted with permission from reference (117). Copyright 2013 American Chemical Society.). 245 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Figure 29. Preparation and structure of the EFAs mixture from ESO (113). (Adapted with permission from reference (113). Copyright 2014 Royal Society of Chemistry.).

The crosslinks in the PSAs impart the PSAs sufficient cohesion strength. More interestingly, the PSAs contain -OH and a small amount of unreacted -COOH groups. It has been well documented that these functional groups in PSAs can significantly improve the adhesion strength of the PSAs through formations of hydrogen bonds between the PSAs and adherends. The -OH and -COOH groups could also improve the wetting of the PSAs on various adherends and facilitate the intimate contact between the PSAs and the adherends. The -OH and -COOH groups also allow formations of hydrogen bonds among molecular chains and within the same molecular chain of the PSAs, thus increasing the cohesive strength of the PSAs (126, 127).

2.2.1.4. ESO as a Crosslinker for PSAs Besides functioning as a binder, ESO was also used as a crosslinker for PSA applications. A class of PSAs was reported to be developed from renewable methyl oleate (MO) and fully evaluated for their peel strength, tack force and shear resistance. MO was epoxidized and selectively hydrolyzed on the ester group to form epoxidized oleic acid (EOA) as a binder that is a bifunctional monomer containing both a carboxylic acid group and an epoxy group. EOA was step-growth polymerized to form a hydroxyl-containing polyester, which was then cured in the presence of a small amount of ESO to afford PSAs. The step-growth polymerization of EOA is shown in Figure 30 (116). 246 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

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Figure 30. Proposed step-growth polymerization of EOA (116). (Adapted with permission from reference (116). Copyright 2014 John Wiley and Sons.). ESO had multiple epoxy groups on each ESO molecule, and could consume the carboxylic acid groups of the impurities and crosslink the carboxylic acid groups at the chain end of PEOA. ESO was theoretically able to increase the molecular weight.

References 1.

David, S. B.; Sathiyalekshmi, K.; Raj, G. A. G. Studies on acrylated epoxydised triglyceride resin-co-butyl methacrylate towards the development of biodegradable pressure sensitive adhesives. J. Mater. Sci.: Mater. Med. 2009, 20 (1), 61–70. 2. Li, K.; Peshkova, S.; Geng, X. Investigation of soy protein-Kymene® adhesive systems for wood composites. J. Am. Oil Chem. Soc. 2004, 81 (5), 487–491. 3. Biresaw, G.; Liu, Z. S.; Erhan, S. Z. Investigation of the surface properties of polymeric soaps obtained by ring‐opening polymerization of epoxidized soybean oil. J. Appl. Polym. Sci. 2008, 108 (3), 1976–1985. 4. Huang, J.; Li, K. A new soy flour-based adhesive for making interior type II plywood. J. Am. Oil Chem. Soc. 2008, 85 (1), 63–70. 5. Sharma, B. K.; Adhvaryu, A.; Erhan, S. Z. Synthesis of hydroxy thio-ether derivatives of vegetable oil. J. Agric. Food Chem. 2006, 54 (26), 9866–9872. 6. Tsujimoto, T.; Uyama, H.; Kobayashi, S. Green Nanocomposites from Renewable Resources: Biodegradable Plant Oil‐Silica Hybrid Coatings. Macromol. Rapid Commun. 2003, 24 (12), 711–714. 7. Seniha Güner, F.; Yağcı, Y.; Tuncer Erciyes, A. Polymers from triglyceride oils. Prog. Polym. Sci. 2006, 31 (7), 633–670. 8. Sharma, V.; Kundu, P. P. Addition polymers from natural oils-a review. Prog. Polym. Sci. 2006, 31 (11), 983–1008. 9. Soucek, M. D.; Khattab, T.; Wu, J. Review of autoxidation and driers. Prog. Org. Coat. 2012, 73 (4), 435–454. 10. Sharma, V.; Kundu, P. P. Condensation polymers from natural oils. Prog. Polym. Sci. 2008, 33 (12), 1199–1215. 247 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

Downloaded by MICHIGAN STATE UNIV on February 18, 2015 | http://pubs.acs.org Publication Date (Web): December 23, 2014 | doi: 10.1021/bk-2014-1178.ch010

11. Deffar, D.; Teng, G.; Soucek, M. D. Inorganic-organic hybrid coatings based on bodied soybean oil. Surf. Coat. Int., Part B 2001, 84 (2), 147–156. 12. Meier, M. A.; Metzger, J. O.; Schubert, U. S. Plant oil renewable resources as green alternatives in polymer science. Chem. Soc. Rev. 2007, 36 (11), 1788–1802. 13. Xia, Y.; Larock, R. C. Vegetable oil-based polymeric materials: synthesis, properties, and applications. Green Chem. 2010, 12 (11), 1893–1909. 14. Montero de Espinosa, L.; Meier, M. A. Plant oils: The perfect renewable resource for polymer science?! Eur. Polym. J. 2011, 47 (5), 837–852. 15. Wicks Jr, Z. W.; Jones, F. N.; Pappas, S. P.; Wicks, D. A. Organic coatings: science and technology; John Wiley & Sons: 2007. 16. Khot, S. N.; Lascala, J. J.; Can, E.; Morye, S. S.; Williams, G. I.; Palmese, G. R.; Wool, R. P. Development and application of triglyceride‐based polymers and composites. J. Appl. Polym. Sci. 2001, 82 (3), 703–723. 17. Desroches, M.; Escouvois, M.; Auvergne, R.; Caillol, S.; Boutevin, B. From vegetable oils to polyurethanes: synthetic routes to polyols and main industrial products. Polym. Rev. 2012, 52 (1), 38–79. 18. Li, F.; Hanson, M. V.; Larock, R. C. Soybean oil-divinylbenzene thermosetting polymers: synthesis, structure, properties and their relationships. Polymer 2001, 42 (4), 1567–1579. 19. Li, F.; Perrenoud, A.; Larock, R. C. Thermophysical and mechanical properties of novel polymers prepared by the cationic copolymerization of fish oils, styrene and divinylbenzene. Polymer 2001, 42 (26), 10133–10145. 20. Li, F.; Larock, R. C. New soybean oil‐styrene‐divinylbenzene thermosetting copolymers. III. Tensile stress–strain behavior. J. Polym. Sci., Part B: Polym. Phys. 2001, 39 (1), 60–77. 21. Williams, G. I.; Wool, R. P. Composites from natural fibers and soy oil resins. Appl. Compos. Mater. 2000, 7 (5−6), 421–432. 22. Ren, X.; Li, K. Investigation of vegetable‐oil‐based coupling agents for kenaf‐fiber‐reinforced unsaturated polyester composites. J. Appl. Polym. Sci. 2013, 128 (2), 1101–1109. 23. Larock, R. C.; Dong, X.; Chung, S.; Reddy, C. K.; Ehlers, L. E. Preparation of conjugated soybean oil and other natural oils and fatty acids by homogeneous transition metal catalysis. J. Am. Oil Chem. Soc. 2001, 78 (5), 447–453. 24. Kundu, P. P.; Larock, R. C. Novel conjugated linseed oil-styrenedivinylbenzene copolymers prepared by thermal polymerization. 1. Effect of monomer concentration on the structure and properties. Biomacromolecules 2005, 6 (2), 797–806. 25. Henna, P. H.; Andjelkovic, D. D.; Kundu, P. P.; Larock, R. C. Biobased thermosets from the free‐radical copolymerization of conjugated linseed oil. J. Appl. Polym. Sci. 2007, 104 (2), 979–985. 26. Valverde, M.; Andjelkovic, D.; Kundu, P. P.; Larock, R. C. Conjugated low‐saturation soybean oil thermosets: Free‐radical copolymerization with dicyclopentadiene and divinylbenzene. J. Appl. Polym. Sci. 2008, 107 (1), 423–430. 27. Styrene, 12th Report on Carcinogens; National Institute of Environmental Health Science: 2011. 248 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

Downloaded by MICHIGAN STATE UNIV on February 18, 2015 | http://pubs.acs.org Publication Date (Web): December 23, 2014 | doi: 10.1021/bk-2014-1178.ch010

28. Ye, G.; Courtecuisse, F.; Allonas, X.; Ley, C.; Croutxe-Barghorn, C.; Raja, P.; Bescond, G. Photoassisted oxypolymerization of alkyd resins: Kinetics and mechanisms. Prog. Org. Coat. 2012, 73 (4), 366–373. 29. Zhou, C. H. C.; Beltramini, J. N.; Fan, Y. X.; Lu, G. M. Chemoselective catalytic conversion of glycerol as a biorenewable source to valuable commodity chemicals. Chem. Soc. Rev. 2008, 37 (3), 527–549. 30. McCoy, M. Glycerin surplus. Chem. Eng. News 2006, 84 (6), 7–8. 31. Hofland, A. Alkyd resins: From down and out to alive and kicking. Prog. Org. Coat. 2012, 73 (4), 274–282. 32. Kienle, R. H.; Ferguson, C. S. Alkyd resins as film-forming materials. Ind. Eng. Chem. 1929, 21 (4), 349–352. 33. Kienle, R. H. Alkyd Resins. Ind. Eng. Chem. 1949, 41 (4), 726–729. 34. Kraft, W. M. Alkyds-Past, present and future? J. Am. Oil Chem. Soc. 1962, 39 (11), 501–502. 35. Soucek, M.; Johansson, M. K. Alkyds for the 21st century. Prog. Org. Coat. 2012, 73 (4), 273. 36. Ang, D. T. C.; Gan, S. N. Novel approach to convert non-self drying palm stearin alkyds into environmental friendly UV curable resins. Prog. Org. Coat. 2012, 73 (4), 409–414. 37. Cakić, S. M.; Ristić, I. S.; Jašo, V. M.; Radičević, R. Ž.; Ilić, O. Z.; Simendić, J. K. Investigation of the curing kinetics of alkyd–melamine–epoxy resin system. Prog. Org. Coat. 2012, 73 (4), 415–424. 38. Dziczkowski, J.; Soucek, M. D. Factors influencing the stability and film properties of acrylic/alkyd water-reducible hybrid systems using a response surface technique. Prog. Org. Coat. 2012, 73 (4), 330–343. 39. Dziczkowski, J.; Chatterjee, U.; Soucek, M. Route to co-acrylic modified alkyd resins via a controlled polymerization technique. Prog. Org. Coat. 2012, 73 (4), 355–365. 40. Dziczkowski, J.; Dudipala, V.; Soucek, M. D. Investigation of grafting sites of acrylic monomers onto alkyd resins via gHMQC two-dimensional NMR: Part 1. Prog. Org. Coat. 2012, 73 (4), 294–307. 41. Dziczkowski, J.; Dudipala, V.; Soucek, M. D. Grafting sites of acrylic mixed monomers onto unsaturated fatty acids: Part 2. Prog. Org. Coat. 2012, 73 (4), 308–320. 42. Thanamongkollit, N.; Miller, K. R.; Soucek, M. D. Synthesis of UV-curable tung oil and UV-curable tung oil based alkyd. Prog. Org. Coat. 2012, 73 (4), 425–434. 43. Wicks, D. A.; Wicks, Z. W., Jr. Autoxidizable urethane resins. Prog. Org. Coat. 2005, 54 (3), 141–149. 44. Moad, G.; Rizzardo, E.; Thang, S. H. Living radical polymerization by the RAFT process. Aust. J. Chem. 2005, 58 (6), 379–410. 45. Saravari, O.; Praditvatanakit, S. Preparation and properties of urethane alkyd based on a castor oil/jatropha oil mixture. Prog. Org. Coat. 2013, 76 (4), 698–704. 46. Chittavanich, P.; Miller, K.; Soucek, M. D. A photo-curing study of a pigmented UV-curable alkyd. Prog. Org. Coat. 2012, 73 (4), 392–400. 249 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

Downloaded by MICHIGAN STATE UNIV on February 18, 2015 | http://pubs.acs.org Publication Date (Web): December 23, 2014 | doi: 10.1021/bk-2014-1178.ch010

47. Lindeboom, J. Air-drying high solids alkyd pants for decorative coatings. Prog. Org. Coat. 1997, 34 (1), 147–151. 48. Weiss, K. D. Paint and coatings: a mature industry in transition. Prog. Polym. Sci. 1997, 22 (2), 203–245. 49. Zabel, K. H.; Klaasen, R. P.; Muizebelt, W. J.; Gracey, B. P.; Hallett, C.; Brooks, C. D. Design and incorporation of reactive diluents for air-drying high solids alkyd paints. Prog. Org. Coat. 1999, 35 (1), 255–264. 50. Muizebelt, W. J.; Hubert, J. C.; Nielen, M. W. F.; Klaasen, R. P.; Zabel, K. H. Crosslink mechanisms of high-solids alkyd resins in the presence of reactive diluents. Prog. Org. Coat. 2000, 40 (1), 121–130. 51. Hintze-Brüning, H. Utilization of vegetable oils in coatings. Ind. Crops Prod. 1992, 1 (2), 89–99. 52. Nalawade, P. P.; Mehta, B.; Pugh, C.; Soucek, M. D. Modified soybean oil as a reactive diluent: Synthesis and characterization. J. Polym. Sci., Part A: Polym. Chem. 2014, 52 (21), 3045–3059. 53. Thanamongkollit, N.; Soucek, M. D. Synthesis and properties of acrylate functionalized alkyds via a Diels-Alder reaction. Prog. Org. Coat. 2012, 73 (4), 382–391. 54. Quirino, R. L.; Larock, R. C. Rh-based biphasic isomerization of carboncarbon double bonds in natural oils. J. Am. Oil Chem. Soc. 2012, 89 (6), 1113–1124. 55. Pan, X.; Sengupta, P.; Webster, D. C. High biobased content epoxy-anhydride thermosets from epoxidized sucrose esters of fatty acids. Biomacromolecules 2011, 12 (6), 2416–2428. 56. Pan, X.; Webster, D. C. Impact of structure and functionality of core polyol in highly functional biobased epoxy resins. Macromol. Rapid Commun. 2011, 32 (17), 1324–1330. 57. Nelson, T. J.; Galhenage, T. P.; Webster, D. C. Catalyzed crosslinking of highly functional biobased epoxy resins. J. Coat. Technol. Res. 2013, 10 (5), 589–600. 58. Pan, X.; Sengupta, P.; Webster, D. C. Novel biobased epoxy compounds: epoxidized sucrose esters of fatty acids. Green Chem. 2011, 13 (4), 965–975. 59. Pfister, D. P.; Xia, Y.; Larock, R. C. Recent Advances in Vegetable Oil‐Based Polyurethanes. ChemSusChem. 2011, 4 (6), 703–717. 60. Petrović, Z. S. Polyurethanes from vegetable oils. Polym. Rev. 2008, 48 (1), 109–155. 61. Pan, X.; Webster, D. C. New biobased high functionality polyols and their use in polyurethane coatings. ChemSusChem. 2012, 5 (2), 419–429. 62. Chen, Z.; Chisholm, B. J.; Patani, R.; Wu, J. F.; Fernando, S.; Jogodzinski, K.; Webster, D. C. Soy-based UV-curable thiol-ene coatings. J. Coat. Technol. Res. 2010, 7 (5), 603–613. 63. Hoyle, C. E.; Lee, T. Y.; Roper, T. Thiol-enes: Chemistry of the past with promise for the future. J. Polym. Sci., Part A: Polym. Chem. 2004, 42 (21), 5301–5338. 64. Wu, J. F.; Fernando, S.; Weerasinghe, D.; Chen, Z.; Webster, D. C. Synthesis of Soybean Oil‐Based Thiol Oligomers. ChemSusChem. 2011, 4 (8), 1135–1142. 250 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

Downloaded by MICHIGAN STATE UNIV on February 18, 2015 | http://pubs.acs.org Publication Date (Web): December 23, 2014 | doi: 10.1021/bk-2014-1178.ch010

65. Yan, J.; Ariyasivam, S.; Weerasinghe, D.; He, J.; Chisholm, B.; Chen, Z.; Webster, D. Thiourethane thermoset coatings from bio‐based thiols. Polym. Int. 2012, 61 (4), 602–608. 66. Teng, G.; Soucek, M. D. Epoxidized soybean oil-based ceramer coatings. J. Am. Oil Chem. Soc. 2000, 77 (4), 381–387. 67. Sailer, R. A.; Soucek, M. D. Oxidizing alkyd ceramers. Prog. Org. Coat. 1998, 33 (1), 36–43. 68. Teng, G.; Soucek, M. D. Blown soybean oil ceramer coatings for corrosion protection. Macromol. Mater. Eng. 2003, 288 (11), 844–851. 69. Deffar, D.; Teng, G.; Soucek, M. D. Comparison of Titanium‐Oxo‐Clusters Derived from Sol‐Gel Precursors with TiO2 Nanoparticles in Drying Oil Based Ceramer Coatings. Macromol. Mater. Eng. 2001, 286 (4), 204–215. 70. Teng, G.; Wegner, J. R.; Hurtt, G. J.; Soucek, M. D. Novel inorganic/organic hybrid materials based on blown soybean oil with sol-gel precursors. Prog. Org. Coat. 2001, 42 (1), 29–37. 71. Liu, Y.; Li, K. Development and characterization of adhesives from soy protein for bonding wood. Int. J. Adhes. Adhes. 2007, 27 (1), 59–67. 72. Liu, Y.; Li, K. Modification of soy protein for wood adhesives using mussel protein as a model: the influence of a mercapto group. Macromol. Rapid Commun. 2004, 25 (21), 1835–1838. 73. Schwarzkopf, M.; Huang, J.; Li, K. Effects of adhesive application methods on performance of a soy-based adhesive in oriented strandboard. J. Am. Oil Chem. Soc. 2009, 86 (10), 1001–1007. 74. Gu, K.; Li, K. Preparation and evaluation of particleboard with a soy flourpolyethylenimine-maleic anhydride adhesive. J. Am. Oil Chem. Soc. 2011, 88 (5), 673–679. 75. Prasittisopin, L.; Li, K. A new method of making particleboard with a formaldehyde-free soy-based adhesive. Composites, Part A 2010, 41 (10), 1447–1453. 76. Huang, J.; Gu, K.; Li, K. Development and evaluation of new curing agents derived from glycerol for formaldehyde-free soy-based adhesives in wood composites. Holzforschung 2013, 67 (6), 659–665. 77. Jang, Y.; Huang, J.; Li, K. A new formaldehyde-free wood adhesive from renewable materials. Int. J. Adhes. Adhes. 2011, 31 (7), 754–759. 78. Lei, H.; Du, G.; Wu, Z.; Xi, X.; Dong, Z. Cross-linked soy-based wood adhesives for plywood. Int. J. Adhes. Adhes. 2014, 50, 199–203. 79. Liteplo, R. G.; Meek, M. E. Inhaled formaldehyde: exposure estimation, hazard characterization, and exposure-response analysis. J. Toxicol. Environ. Health, Part B 2003, 6 (1), 85–114. 80. Fonnaldehyde, International Agency for Research on Cancer classifies formaldehyde as carcinogenic to humans; International Agency for Research on Cancer, 2004; Press release no. 153. 81. Lambuth, A. L. Adhesives from renewable resources: Historical perspective and wood industry needs. In Adhesives from renewable resources; ACS Symposium Series 385; American Chemical Society: Washington, DC, U.S.A., 1989. 251 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

Downloaded by MICHIGAN STATE UNIV on February 18, 2015 | http://pubs.acs.org Publication Date (Web): December 23, 2014 | doi: 10.1021/bk-2014-1178.ch010

82. Soybean crop a record-breaker USDA Reports, Crop Production Summary Provides Final 2006 Totals for Major Crops; United States Department of Agriculture: Washington, DC, 2007. 83. Wolf, W. J.; Cowan, J. C.; Wolff, H. Soybeans as a food source. Crit. Rev. Food Sci. Nutr. 1971, 2 (1), 81–158. 84. Wolf, W. J. Soybean proteins. Their functional, chemical, and physical properties. J. Agric. Food Chem. 1970, 18 (6), 969–976. 85. Seal, R. Industrial soya protein technology. Appl. Protein Chem. 1980. 86. Kumar, R.; Choudhary, V.; Mishra, S.; Varma, I. K.; Mattiason, B. Adhesives and plastics based on soy protein products. Ind. Crops Prod. 2002, 16 (3), 155–172. 87. Kinsella, J. E. Functional properties of soy proteins. J. Am. Oil Chem. Soc. 1979, 56 (3), 242–258. 88. Zarkadas, C. G.; Yu, Z.; Voldeng, H. D.; Minero-Amador, A. Assessment of the protein quality of a new high-protein soybean cultivar by amino acid analysis. J. Agric. Food Chem. 1993, 41 (4), 616–623. 89. Lin, Q.; Chen, N.; Bian, L.; Fan, M. Development and mechanism characterization of high performance soy-based bio-adhesives. Int. J. Adhes. Adhes. 2012, 34, 11–16. 90. Gui, C.; Wang, G.; Wu, D.; Zhu, J.; Liu, X. Synthesis of a bio-based polyamidoamine-epichlorohydrin resin and its application for soy-based adhesives. Int. J. Adhes. Adhes. 2013, 44, 237–242. 91. Qi, G.; Sun, X. S. Peel adhesion properties of modified soy protein adhesive on a glass panel. Ind. Crops Prod. 2010, 32 (3), 208–212. 92. Lambuth, A.L. Soybean glues. In Handbook of Adhesives, 2nd ed.; Skeist, I., Ed.; Van Norstrand-Reinhold Publication: New York, NY, 1977. 93. Lorenz, L. F.; Conner, A. H.; Christiansen, A. W. Effect of soy protein additions on the reactivity and formaldehyde emissions of urea-formaldehyde adhesive resins. For. Prod. J. 1999, 49 (3), 73–78. 94. Kuo, M.; Adams, D.; Myers, D.; Curry, D.; Heemstra, H.; Smith, J. L.; Bian, Y. Properties of wood/agricultural fiberboard bonded with soybeanbased adhesives. For. Prod. J. 1998, 48 (2), 71–75. 95. Kreibicha, R. E.; Steynberg, P. J.; Hemingway, R. W. End jointing green lumber with SoyBond. Residual Wood Conference Proceedings 1997, 2, 28−36. 96. Guezguez, B.; Irle, M.; Belloncle, C. Substitution of formaldehyde based adhesives with soy based adhesives in production of low formaldehyde emission wood based panels. Part 1-Plywood. Int. Wood Prod. J. 2013, 4 (1), 30–32. 97. Qi, G.; Sun, X. S. Soy protein adhesive blends with synthetic latex on wood veneer. J. Am. Oil Chem. Soc. 2011, 88 (2), 271–281. 98. Hettiarachchy, N. S.; Kalapathy, U.; Myers, D. J. Alkali-modified soy protein with improved adhesive and hydrophobic properties. J. Am. Oil Chem. Soc. 1995, 72 (12), 1461–1464. 99. Kumar, R.; Choudhary, V.; Mishra, S.; Varma, I. K. Enzymatically-modified soy protein part 2: adhesion behaviour. J. Adhes. Sci. Technol. 2004, 18 (2), 261–273. 252 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

Downloaded by MICHIGAN STATE UNIV on February 18, 2015 | http://pubs.acs.org Publication Date (Web): December 23, 2014 | doi: 10.1021/bk-2014-1178.ch010

100. Huang, W.; Sun, X. Adhesive properties of soy proteins modified by urea and guanidine hydrochloride. J. Am. Oil Chem. Soc. 2000, 77 (1), 101–104. 101. Huang, W.; Sun, X. Adhesive properties of soy proteins modified by sodium dodecyl sulfate and sodium dodecylbenzene sulfonate. J. Am. Oil Chem. Soc. 2000, 77 (7), 705–708. 102. Chen, N.; Lin, Q.; Rao, J.; Zeng, Q.; Luo, X. Environmentally friendly soy-based bio-adhesive: preparation, characterization, and its application to plywood. BioResources 2012, 7 (3), 4273–4283. 103. Gui, C.; Liu, X.; Wu, D.; Zhou, T.; Wang, G.; Zhu, J. Preparation of a New Type of Polyamidoamine and Its Application for Soy Flour-Based Adhesives. J. Am. Oil Chem. Soc. 2013, 90 (2), 265–272. 104. Rzepecki, L. M.; Chin, S. S.; Waite, J. H.; Lavin, M. F. Molecular diversity of marine glues: polyphenolic proteins from five mussel species. Mol. Mar. Biol. Biotechnol. 1991, 1 (1), 78–88. 105. Rzepecki, L. M.; Waite, J. H. DOPA proteins: versatile varnishes and adhesives from marine fauna. In Bioorganic marine chemistry; Springer: Berlin, Heidelberg, 1991; pp 119−148. 106. Qin, X. X.; Coyne, K. J.; Waite, J. H. Tough Tendons Mussel Byssus Has Collagen with Silk-Like Domains. J. Biol. Chem. 1997, 272 (51), 32623–32627. 107. Coyne, K. J.; Qin, X. X.; Waite, J. H. Extensible collagen in mussel byssus: a natural block copolymer. Science 1997, 277 (5333), 1830–1832. 108. Liu, Y.; Li, K. Chemical modification of soy protein for wood adhesives. Macromol. Rapid Commun. 2002, 23 (13), 739–742. 109. Rzepecki, L. M.; Hansen, K. M.; Waite, J. H. Characterization of a cystinerich polyphenolic protein family from the blue mussel Mytilus edulis L. Biol. Bull. 1992, 183 (1), 123–137. 110. Creighton, T. E. Proteins: structures and molecular properties; Macmillan: 1993. 111. Takasaki, S.; Kawakishi, S. Formation of protein-bound 3, 4-dihydroxyphenylalanine and 5-S-cysteinyl-3, 4-dihydroxyphenylalanine as new cross-linkers in gluten. J. Agric. Food Chem. 1997, 45 (9), 3472–3475. 112. Zhu, D.; Damodaran, S. Chemical phosphorylation improves the moisture resistance of soy flour‐based wood adhesive. J. Appl. Polym. Sci. 2014, 131 (13), 40451. 113. Li, A.; Li, K. Pressure-sensitive adhesives based on soybean fatty acids. RSC Adv. 2014, 4 (41), 21521–21530. 114. Li, A.; Li, K. Pressure-Sensitive Adhesives Based on Epoxidized Soybean Oil and Dicarboxylic Acids. ACS Sustainable Chem. Eng. 2014, 2 (8), 2090–2096. 115. David, S. B.; Sathiyalekshmi, K.; Raj, G. A. G. Studies on acrylated epoxydised triglyceride resin-co-butyl methacrylate towards the development of biodegradable pressure sensitive adhesives. J. Mater. Sci.: Mater. Med. 2009, 20 (1), 61–70. 116. Wu, Y.; Li, A.; Li, K. Development and evaluation of pressure sensitive adhesives from a fatty ester. J. Appl. Polym. Sci. 2014, 131, 41143. 253 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.

Downloaded by MICHIGAN STATE UNIV on February 18, 2015 | http://pubs.acs.org Publication Date (Web): December 23, 2014 | doi: 10.1021/bk-2014-1178.ch010

117. Vendamme, R.; Eevers, W. Sweet Solution for Sticky Problems: Chemoreological Design of Self-Adhesive Gel Materials Derived From Lipid Biofeedstocks and Adhesion Tailoring via Incorporation of Isosorbide. Macromolecules 2013, 46 (9), 3395–3405. 118. Ahn, B. K.; Kraft, S.; Wang, D.; Sun, X. S. Thermally stable, transparent, pressure-sensitive adhesives from epoxidized and dihydroxyl soybean oil. Biomacromolecules 2011, 12 (5), 1839–1843. 119. Bunker, S.; Staller, C.; Willenbacher, N.; Wool, R. Miniemulsion polymerization of acrylated methyl oleate for pressure sensitive adhesives. Int. J. Adhes. Adhes. 2003, 23 (1), 29–38. 120. Bunker, S. P.; Wool, R. P. Synthesis and characterization of monomers and polymers for adhesives from methyl oleate. J. Polym. Sci., Part A: Polym. Chem. 2002, 40 (4), 451–458. 121. Klapperich, C. M.; Noack, C. L.; Kaufman, J. D.; Zhu, L.; Bonnaillie, L.; Wool, R. P. A novel biocompatible adhesive incorporating plant‐derived monomers. J. Biomed. Mater. Res., Part A 2009, 91 (2), 378–384. 122. Ahn, B. J. K.; Kraft, S.; Sun, X. S. Chemical pathways of epoxidized and hydroxylated fatty acid methyl esters and triglycerides with phosphoric acid. J. Mater. Chem. 2011, 21 (26), 9498–9505. 123. Ahn, B. K.; Sung, J.; Sun, X. S. Phosphate Esters Functionalized Dihydroxyl Soybean Oil Tackifier of Pressure-Sensitive Adhesives. J. Am. Oil Chem. Soc. 2012, 89 (5), 909–915. 124. Guo, Y.; Hardesty, J. H.; Mannari, V. M.; Massingill, J. L., Jr Hydrolysis of epoxidized soybean oil in the presence of phosphoric acid. J. Am. Oil Chem. Soc. 2007, 84 (10), 929–935. 125. Nyk, A.; Klosinski, P.; Penczek, S. Water‐swelling, hydrolyzable gels through polyaddition of H3PO4 to diepoxides. Die Makromol. Chem. 1991, 192 (4), 833–846. 126. Gay, C. Stickiness-Some fundamentals of adhesion. Integr. Comp. Biol. 2002, 42 (6), 1123–1126. 127. Bellamine, A.; Degrandi, E.; Gerst, M.; Stark, R.; Beyers, C.; Creton, C. Design of nanostructured waterborne adhesives with improved shear resistance. Macromol. Mater. Eng. 2011, 296 (1), 31–41.

254 In Soy-Based Chemicals and Materials; Brentin; ACS Symposium Series; American Chemical Society: Washington, DC, 2014.